Bipolar transistor and method of producing the same

ABSTRACT

A dummy emitter (a dummy collector, in an inverted type) is formed in the portion corresponding to an emitter (a collector, in the inverted type) region, on a multiplayer structural material including layers for forming emitter, base and collector, and using it as mask, an external base region is exposed by etching, and a projection of the emitter (the collector, in the inverted type) region is formed, while the dummy emitter (the dummy collector, in the inverted type) is inverted into an emitter (a collector, in the inverted type) electrode, thereby forming an emitter (a collector, in the inverted type) electrode metal layer covering the whole upper surface of the emitter (the collector, in the inverted type). Using the thus formed emitter (the collector, in the inverted type) electrode metal layer, a base electrode metal layer is formed, by self-alignment, adjacent to the emitter (the collector, in the inverted type). In another method, on a multilayer structural material, impurities are introduced outside the portion corresponding to the base region of a bipolar transistor in order to insulate, at least, a portion of the layer forming the base, and if necessary a portion of the layer forming the emitter and a portion of the layer forming the collector. Further, an extension layers and the layer forming the collector, and an extension type dummy emitter (a dummy collector, in the inverted type) is formed which extends from the emitter (the collector, in the inverted type) on the base portion to the insulating region formed by transforming from the semiconductor material forming the base, and using it as mask, the external base region is exposed to form an emitter-including layer and the dummy emitter (the dummy collector, in the inverted type) is replaced by an emitter (a collector, in the inverted type) electrode metal layer covering the whole upper surface of the emitter-including layer.

This application is a continuation of now abandoned application, Ser. No. 07/030,607 filed on Mar. 27, 1987 now abandoned

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to a superhigh-speed, superhigh-frequency biopolar transistor device.

2. Description of the Prior Art

The current gain cut-off frequency f_(T) and the power gain cut-off frequency f_(m) of a bipolar transistor (BT) are expressed as follows. ##EQU1## where τe (emitter depletion layer charging time)=re (Cbc +Ceb), τb (base transit time of minority carriers)=Wb² /2Db, τc (collector depletion layer transit time of minority carriers)=Wc/2Vs, τcc (collector depletion layer charging time)=(Ree+Rc) Cbc, Rb: base resistance, Cbc: base-collector capacitance, Ceb: base-emitter capacitance, Wb: base layer thickness, Db: base diffusion coefficient of minority carriers, Wc: collector depletion layer thickness, Vs: collector saturation velocity of minority carriers, re: emitter resistance, Ree: emitter-contact resistance, and Rc: collector resistance. <Large values of f_(T) and f_(m) are required for high speed operation of BT.>

In the BT, as is clear from the formulae above, to increase f_(T) and f_(m), it is necessary to decrease the capacitances of Cbc and Ceb, the thickness of base layer, the base resistance, the emitter resistance, and the collector resistance. In particular, to obtain a large f_(m), it is necessary to reduce Rb and Cbc. For these purposes, it is extremely important to reduce the size of each part of BT, optimize the electrode layout, and optimize the process to lower the contact resistance of the electrodes, and various attempts have been made in these directions.

It has been reported by H. Kroemer that the heterojunction bipolar transistor (HBT) using a semiconductor material having a wider energy band gap than that of the base as the emitter is intrinsically superior to an ordinary BT (H. Kroemer, "Heterostructure Bipolar Transistors and Integrated Circuits", Proc. IEEE, vol, 70, P. 13, 1982). In the HBT, injection of holes from the base to the emitter is restricted (in the case of an NPN transistor), and hence it is possible to construct a base having a higher doping density and having an emitter and collector at a lower doping density than those of an ordinary BT. Therefore, it is intrinsically advantageous for the reduction of the base resistance Rb, the emitter-base junction capacitance Cjeb and the base-collector junction capacitance Cjbc. Since the emitter and collector are at low doping densities and the base is at a very high doping density, Cjeb and Cjbc are expressed as follows: ##EQU2## where ne and nc are the doping density concentrations of the emitter and collector, and Ajeb and Ajbc are the junction areas of emitter and base, and base and collector, respectively. Therefore, Cjeb and Cjbc can be intrinsically reduced.

However, to utilize the above-described features effectively, the device structure and process should be optimized to reduce parasitic elements of resistance and capacitance. For this purpose, some methods have been attempted.

P.M. Asbeck et al. has reported a method to reduce the collector size by implanting oxygen ions into the collector layer. (P.M. Asbeck et al., "GaAs/(Ga, Al) As Heterojunction Bipolar Transistors with Buried Oxygen-Implanted Isolation Layer", Election Device Lett., vol. EDL-5, P. 310, 1984). However, the following problems occur in this method. A smaller mask than the buried collector is additionally required to make an emitter electrode. In this case, when the transistor size is made smaller, the mask alignment between the buried collector and the emitter electrode is more difficult. Furthermore, for a metal delineation from the emitter electrode, a different mask may be necessary. This may cause another problem in mask alignment between the emitter electrode and the metal delineation when the transistor size is reduced, and may cause a step structure of the delineation metal at an end of the emitter electrode, and hence may cause the breakage of the delineation metal there.

Nagata et al. has reported a method to form the base electrode very close to the emitter portion by self-alignment and to reduce the external base resistance (Nagata et al., "A New Self-aligned Structure AlGaAs/GaAs HBT for High Speed Digital Circuits," Proc. Symp. on GaAs and Related Compounds (Inst. Phys. Conf. Ser. 790, P. 589, 1985). However, in this process and the structure by it, an emitter mesa and a base mesa are formed, and an emitter electrode is on the emitter mesa and a base electrode is formed very close to the emitter mesa separated by a SiO₂ side wall of the emitter mesa. This may necessitate other masks to form the metal delineation from the emitter electrode and the base electrode, and may form steps of the delineation metals at the ends of the emitter mesa and the base mesa, which may incur breakage of the delineation metal. In this process, the base electrode is formed before the emitter electrode is formed. Hence, there may be limitation in the types of the base electrode metals due to the difference in alloying temperature of the base and emitter electrode.

SUMMARY OF THE INVENTION

It is hence a primary object of this invention, relating to a bipolar transistor (BT) of a normal type having the emitter at the upper side thereof and of an inverted type having the collector at the upper side thereof, to present a first novel method of producing a BT by forming an emitter (a collector, in the case of the inverted type), an emitter (a collector, in the case of the inverted type) electrode, a low resistance external base by introduction of impurities, a buried type collector (an emitter, in the case of the inverted type) by introduction of impurities, and a base electrode positioned at an extremely close distance to the emitter, by self-alignment, using a single mask for forming the emitter (the collector, in the case of the inverted type).

It is another object of this invention to present a second novel method of producing a BT by forming an emitter (a collector, in the inverted type), an emitter (a collector, in the inverted type) electrode, a metal delineation from an emitter (a collector, in the inverted type) electrode, a low resistance external base by introduction of impurities, a buried type collector (an emitter, in the inverted type) by introduction of impurities, a base electrode positioned at an extremely close distance to the emitter, and a metal delineation from a base electrode, by self-alignment, using a single mask for forming the emitter (the collector, in an inverted type).

It is a further object of this invention to present a first novel BT structure comprising an emitter-including layer (that is--a layer including an emitter portion) extending an emitter (a collector, in the inverted type) region to an insulating region formed by converting from semiconductor material forming the base and an emitter (a collector, in the inverted type) electrode metal layer covering the entire surface thereof.

It is a still further object of this invention to present a second novel BT structure possessing a base electrode metal layer positioned in an external base region excluding the base region substantially below or corresponding on a plan view to the emitter (a collector, in the inverted type) electrode in the first BT structure, and extending from the external base region to the insulating region around the base.

It is yet another object of this invention to present a novel BT structure possessing, in addition to the first structure, second structure, or the combination of first and second structure, an external base region having a higher dopant concentration or a greater thickness than the base region below or corresponding on a plan view to the emitter (a collector, in the inverted type) electrode, or a buried type collector (an emitter, in the inverted type) region substantially the same size as the emitter electrode, or both of them.

To achieve the above objects, the following method is applied to form the BT of this invention.

In a first method, on a multilayer structural material containing layers for forming emitter, base and collector, a dummy emitter (a dummy collector, in the inverted type) is formed in the portion corresponding to an emitter (a collector, in the inverted type), an external base is exposed and an emitter-including layer is formed by etching, using this dummy emitter (collector, in the inverted type) as a mask, the surface is coated and flattened with a photosensitive resist, and the top part of the dummy emitter (the collector, in the inverted type) is exposed by dry etching and the dummy emitter is removed by etching, and an emitter (a collector, in the inverted type) electrode metal layer which covers the entire top surface of the emitter-including layer is formed in the formed opening.

In a second method, base electrode metal is evaporated using the umbrella-shaped emitter (the collector, in the inverted type) electrode layer projected around the emitter-including layer (the collector-including layer, in the inverted type) as a mask, which is formed by said first method, and consequently the base electrode layer is formed very close to the emitter-including layer (the collector-including layer, in the inverted type).

In a third method, side walls made of an insulating thin film are disposed on the side of the emitter-including layer (a collector-including layer in the inverted type) and the emitter (the collector, in the inverted type) electrode layer, which are formed by said first method, a base electrode metal is evaporated, the surface is coated and flattened with a photosensitive resist, and the upper surface of the emitter-including layer (the collector-including layer, in the inverted type) is exposed by dry etching, and the base electrode metal depositing on the side wall of the emitter-including layer (the collector-including layer, in the inverted type) is removed by etching, thereby separating the emitter and base electrodes.

In a fourth method, in an intermediate process of the first method, a buried type collector of substantially the same size as the dummy emitter (the dummy collector, in the inverted type) is formed, ions are implanted into the collector (the emitter, in the inverted type) layer using the dummy emitter (the dummy collector, in the inverted type) as a mask and insulating the ion-implanted region by it.

In a fifth method, in an intermediate process of the first method, a dopant different in concentration or kind from the dopant in the base region is introduced into the external base region outside of the base region below or corresponding on a plan view to the dummy emitter (the collector, in the inverted type), using the dummy emitter (the collector, in the inverted type) as a mask, and consequently an external base of higher concentration or greater thickness is formed.

A sixth method comprises a step of forming a base isolation region by implanting ions into at least the layer forming the base on the outside of the base region, from above onto a multilayer structural material, a step of forming an extension type dummy emitter (a dummy collector, in the inverted type) having a structure extended from the emitter (the collector, in the inverted type) region to the formed base isolation region, a step of forming an extension type emitter (the collector, in the inverted type) region to the formed base isolation region, by exposing the external base region by etching, using the extension type dummy emitter (the dummy collector, in the inverted type) as a mask, and a step of inverting the extension type dummy emitter (the dummy collector, in the inverted type) into an emitter (a collector, in the inverted type) electrode metal layer.

In seventh and eighth methods, using the extension type emitter-including layer (the collector-including layer, in the inverted type) formed by the sixth method and the emitter (the collector, in the inverted type) electrode metal layer to cover its whole upper surface, a base electrode metal layer positioned very close to the emitter-including layer (the collector-including layer, in the inverted type) and extending from the external base region to the base isolation region is formed by applying the second and third methods.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1(a)-1(c) show an example of the structure of a bipolar transistor of this invention, in which FIG. 1(a) is a layout plan of parts, FIG. 1(b) is a front section view, and FIG. 1(c) is a side sectional view;

FIG. 2 is a sectional view showing the relationship of the emitter electrode metal layer and a thick external base region formed by self-alignment of a bipolar transistor of this invention;

FIGS. 3, 4, 5 are sectional views showing the configuration of the emitter electrode metal layer, the emitter portion and the base electrode metal layer of a bipolar transistor of this invention;

FIGS. 6(a)-(g), 7(a)-(b), 8(a) a)-(b), 9(a)-(e), and 10 are sectional views indicating the method of forming the emitter electrode metal layer by inverting from the dummy emitter, in which FIGS. 6(a)-(g) relate to a case of covering the entire upper surface of emitter, with the emitter electrode metal layer substantially same in size as the emitter, FIGS. 7(a)-(b) show the emitter electrode metal layer covering the upper surface of the emitter in a form of an umbrella, FIGS. 8(a)-(b) refer to a case of placing a semiconductor material layer greater in the work function than the electrode metal, between the emitter electrode metal layer and emitter shown in FIGS. 6(a)-(g), FIGS. 9(a)-(b) denote a case of placing the emitter electrode metal layer on the emitter to cover its upper surface in a mushroom shape, and FIG. 10 shows a case of using Al_(x) Ga_(1-x) AS (x≧0.4) as a protective film of emitter-contact layer in the process shown in FIGS. 9(a)-(b);

FIGS. 11 and 12 are sectional views showing the method of forming a low resistance external base region in self-alignment with the emitter by ion implantation as a mask in which FIG. 11 shows a case of forming a high doping density external base region and FIG. 12 refers to a case of forming a thick external base region;

FIG. 13 denotes a method of forming a buried type collector region, in self-alignment with the emitter by ion implantation, using the dummy emitter as a mask;

FIG. 14 shows a method of forming a buried type collector region in self-alignment with the emitter by ion implantation, using the emitter electrode metal layer as a mask;

FIGS. 15(a)-(b), 16(a)-(c), 17(a)-(d), 18(a)-(b), 19(a)-(b), and 20(a)-(c) represent methods of forming a base electrode metal layer adjacent to the emitter portion in self-alignment with the emitter by using the emitter electrode metal layer or the dummy emitter as a mask in which FIGS. 15(a)-(b) show a method of forming a base electrode metal layer using an umbrella-shaped emitter electrode metal layer as a mask, FIGS. 16(a)-(c) show a method of forming a base electrode metal layer using the umbrella-shaped emitter electrode metal layer and SiO_(x) side wall formed at its side as a mask, FIGS. 17(a)-(d) show a method of forming a base electrode metal layer using SiO_(x) side wall formed on the side of the emitter and the emitter electrode metal layer covering the upper surface of emitter portion in the same size, FIGS. 18(a)-(b) show a method of forming a base electrode metal layer using a mushroom-shaped emitter electrode metal layer as a mask, FIGS. 19(a)-(b) show a method of forming emitter electrode metal layer after forming a base electrode metal layer in self-alignment with the emitter using the umbrella-shaped dummy emitter as a mask, and FIGS. 20(a)-(c) show a method of forming an emitter electrode metal layer after forming a base electrode metal layer by self-alignment, using a dummy emitter substantially of the same size as the emitter;

FIGS. 21(a)-1 to (b)-3 show a self-alignment forming method of forming an emitter-including layer extended from an emitter region to the base insulation region, and an emitter electrode metal layer to cover the entire surface of the top of this mesa; and

FIGS. 22(a)-(b) show a forming method of forming a base electrode metal layer positioned very close to the emitter portion and extending from the external base region to the base insulation region by using the emitter electrode metal layer of FIG. 21 as a mask.

In the drawing figures, the reference numbers are meant as follows:

1--semi-insulating GaAs substrate, 2--high doping density n-type GaAs, 2a--part of 2 to compose a bipolar transistor, 3--N-type GaAs, 3a--collection region, 3b--insulation region formed by transforming from material of 3, 4--high doping density p-type GaAs, 4a--part of 4 to compose a bipolar transistor, 4b--base region just beneath emitter electrode metal layer or the layer composed of it and side wall, 4c--base region of outside of 4b, 4d--thick outer base region, 5--n-type Al_(x) GA_(1-x) As, 5a--part of 5 to compose a bipolar transistor, 5b--insulating region formed by transforming from the material of 5, 5c--p-type region formed by transforming from the material of 5, 6--high doping density n-type GaAs, 6a--part of 6 to compose a bipolar transistor, 6b--insulating region formed by transforming from the material of 6, 7--multilayer structural material composed of parts 1 to 7, 8--emitter region composed of 5a and 6a, 9--emitter-including layer composed of 8 and 5b, 6b, 10a--emitter electrode metal layer covering the whole upper surface of layer 9 in a form of umbrella, 10b--wiring pattern of emitter electrode, 10c--emitter electrode metal layer covering the whole upper surface of layer 9, having substantially same size as layer 9, 10d--mushroom-shaped emitter electrode metal layer to cover the upper surface of layer 9, 10e--emitter electrode metal layer covering the whole upper surface of emitter, having substantially same size as emitter, 10f--emitter electrode metal layer to cover the whole upper surface of emitter in a form of umbrella, 10g--mushroom-shaped emitter electrode metal layer to cover the whole upper surface of emitter, 11a--base electrode metal layer extending from outer base region to peripheral insulating region, 11b--base electrode wiring pattern or pad, 11c--base electrode formed adjacently to emitter portion, 12a--collector electrode, 12b--collector electrode wiring pattern or pad, 13--insulating region inside transistor, 14--external insulating region isolating transistors from each other, 15--undercut portion by wet etching, 16--multilayer structural material composed of 7, 35 and 36, 17--side wall, 18--SiO_(x) dummy emitter, 19--Al dummy emitter, 20--dummy emitter, 21--photosensitive resist, 22a--opening with exposed 6a, 22b--umbrella-shaped opening with exposed 6b, 23--Al_(x) Ga_(1-x) As (x≧0.4) to protect layer 6, 24--ion implantation (Be⁺, 25--ion implantation (0⁺), 26--ion implantation (H⁺), 27--mask of photosensitive resist, 28--base electrode metal, 29a--base region, 29b--mask in same size as base region, 30--SiO_(x) dummy emitter extending from emitter region to insulating region, 31--Al dummy emitter to cover the whole upper surface of 30, 32--dummy emitter composed of 30 and 31, 33--cross section of bipolar transistor, 34--cross-section of bipolar transistor, 35--n-type In_(x) Ga_(1-x) As (x=0 to 1), 35a--part of 35 formed on emitter portion 8, 36--n-type InAs layer, and 36--part of 36 formed on emitter 8.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

1. FIGS. 1(a)-(c) show an npn type heterojunction bipolar transistor (HBT), as an example of structure of bipolar transistor (BT) of this invention. FIG. 1(a) is a conceptual drawing showing a plan view of the configuration of each part of HBT, and FIG. 1(b) is a sectional view cutting FIG. 1(a) on a plane 33 perpendicular to the paper surface, while FIG. 1(c) is a sectional view cutting FIG. 1(a) on a plane 34 perpendicular to the paper surface.

On the circumference of base region 4a composed of high doping density p-type GaAs (p⁺ -GaAs), there are insulating region 13 formed by transforming from the p⁺ -GaAs and n-type GaAs (n-GaAs) to form collector region 3a, and insulating region 14 formed by transforming from high doping density n-type GaAs (n⁺ -GaAs) layer to form the contact for collector 2a.

The emitter region 8 is composed of part 5a made of n-type Al_(x) Ga_(1-x) As (n-AlGaAs) with a wide energy band gap, and part 6a made of N⁺ -GaAs, and forms the layer 9 coupled with an insulating region composed of 6b and 5b formed by transforming from the semiconductor materials of 6a and 5a.

The emitter electrode metal layer 10a covers the whole upper surface of the layer 9, and has a structure of projecting like an umbrella around the layer 9, and this structure serves both as emitter electrode and as emitter electrode delineation metal or contact lead.

Accordingly, the resistance of the emitter contact is extremely small as compared with that of the conventional HBT. Besides, the wiring pattern 10b can be formed very easily by using a simply mask, and this wiring pattern 10b is also free from wire disconnections due to step breakage, which is a conventional problem, because it contacts with the emitter electrode metal layer 10a on three sides. Moreover, since the emitter electrode metal layer 10a serves both as emitter electrode and as emitter electrode delineation metal, an HBT of an extremely small emitter size may be easily fabricated. Part 6b of layer 9 is insulated in this embodiment, but it is not necessarily insulated. If the part 6b is left in a state of n⁺ -GaAs, the capacitance in the insulating region 14 enclosed between electrode metal layer 10a and N⁺ -GaAs layer 2 is slightly increased, but this change is negligibly small in an HBT of small size. To the contrary, since the area used to form the emitter contact is widened, it is effective to reduce the contact resistance. Similarly, the upper portion of part 5b may be also in an n-type state.

The base electrode metal layer 11a exists in the external base region 4c outside of the base region 4b below or corresponding on a plan view to the umbrella-shaped emitter electrode metal layer 10a, and extends from the external base region 4c to peripheral insulating region 14, working both as base electrode and as base electrode delineation metal or contact lead. Accordingly, the formation of base wiring pattern is extremely easy. Since this electrode layer exists in the same plane, step breakage does not occur. Incidentally, since the electrode layer 11a is formed very close to the emitter part 5a, the external base resistance is greatly reduced.

Below or at a position corresponding on a plan view to the emitter electrode metal layer 10a, a buried type collector 3a substantially of the same size as the emitter electrode portion is formed, together with an insulating region 3b formed by transforming from the same semiconductor material as 3a, on its periphery. Hence the base-collector junction capacitance Cjbc can be greatly decreased.

The base region 4c outside of the base region 4b below or corresponding on a plan view to the emitter electrode is of p-type with a higher doping density than the base region 4b. Accordingly, the external base region possesses a small sheet resistance.

In this embodiment, the HBT comprehensively possessing the features of the parts mentioned above is formed.

In said structure of the HBT, Al_(x) Ga_(1-x) As is used as emitter, and GaAs is used to form other parts, but the same structure may be also applicable to an HBT made of other materials, or to be usual homojunction BT composed of an emitter, base and collector of the same semiconductor material, or a pnp type BT. Moreover, it may also be applied to an inverted type HBT or BT in which the positions of emitter and collector are exchanged so that the collector is on the upper side.

2. FIG. 2 shows a different structure of embodiment 1, wherein the base region 4d outside of the base region 4b below or corresponding on a plan view to the emitter electrode metal layer 10a is a thick external base region composed of a p-type region 5c formed by transforming from the emitter region 5c and external base region 4c of p⁺ -GaAs.

As a result, the sheet resistance of the external base may be reduced. It does not matter at all if the external base region extends to the portion of collector layer 3, and it is contrarily effective to lower the sheet resistance of the external base.

3. FIG. 3 shows another structure of the emitter electrode metal layer 10a and base electrode metal layer 11a in embodiment 1.

In FIG. 3, relating to embodiment 1, the whole upper surface of the emitter-including layer is covered by the emitter electrode metal layer 10c of substantially the same size therewith, a side wall 17 made of SiO_(x) thin film of 3000Å in thickness is formed on the sides around the emitter-including layer and emitter electrode metal 10c, and a base electrode metal layer 11a is formed substantially in contact with the side wall 17, extending from the external base to the peripheral insulating region. The effect is same as mentioned in embodiment 1. As the side wall, meanwhile, other insulating material such as SiN_(x) may be used.

4. FIG. 4 shows a further different composition of embodiment 1, in which a side wall 17 made of thin film of SiO_(x) in 3000Å in thickness is formed on the side of emitter-including layer and emitter electrode metal layer 10a, and a base electrode metal layer 11a is formed substantially in contact with the side wall 17, extending from the external base to the peripheral insulating region 14. As the side wall, other insulating materials such as SiN_(x) may be also used.

5. FIG. 5, also relating to embodiment 1, shows a structure in which the whole upper surface of the emitter-including layer is covered with emitter electrode metal layer having a mushroom-shape spreading to the peripheral parts of the the emitter-including layer, and outside of the base region 4b below or corresponding on a plan view to the mushroom electrode 10d, there is a base electrode metal layer 11a extending from the external base region 4c to the peripheral insulating region 14.

6. FIGS. 6(a)-(g) illustrate a method of fabrication used to form an emitter electrode metal layer 10e which covers the whole upper surface of the emitter-including layer. As shown in FIG. 6(a), on a semi-insulating GaAs substrate 1, a multi-layer structural material 7 composed of n⁺ -GaAs layer 2, n-GaAs layer 3, p⁺ -GaAs layer 4, n-AlGaAs layer 5, and n⁺ -GaAs layer 6 is formed by epitaxial growth.

On this multilayer structural material 7, a 1 μm thick SiO_(x) thin film is formed, and in the portion corresponding to emitter on this film, an Al layer 19 of 5000Å in thickness is formed by evaporating and lifting off, and SiO_(x) layer 18 corresponding to emitter portion is formed by dry etching with CHF₃, using the Al layer 19 as a mask (FIG. 6 (b)). By exposing the external base region 4c by etching, using a dummy emitter 20 composed of SiO_(x) layer 18 and Al layer 19 as a mask, and a protruding emitting region 8 is formed (FIG. 6(c)). In succession, the surface is covered and flattened with photosensitive resist 21 (FIG. 6(d)), and the photosensitive resist 21 is etched by dry etching using oxygen plasma, and the upper part of dummy emitter 20 is exposed (FIG. 6(e)), then, removing the Al layer 19 by hydrochloric acid and also removing SiO_(x) 18 by buffer HF, an opening 22a is formed (FIG. 6(f)). Next, in this opening 22a, AuGe, Ni, Ti and Au are evaporated in this order and lifted off, and an emitter electrode metal layer 10e is formed (FIG. 6(g)). As a result, the emitter electrode metal layer 10e used to cover the whole upper surface of emitter portion 8 is formed. In this embodiment, meanwhile, as the layer used to form dummy emitter, an SiO_(x) layer and an Al layer are used, but instead of SiO_(x), other materials such as SiN_(x) may also be used. Or, instead of Al, other metals may be used, too. Incidentally, after forming the SiO_(x) layer 18 by dry etching, the Al layer 19 is not necessarily required. In this embodiment, the external base region 4c can be made also by etching until close to the external base region using a dummy emitter 20 as a mask, and then by etching up to the external base region using the emitter electrode metal layer as a mask. This has an effect to protect the external base region from being damaged during the process. This process can be applied also to a homojunction BT, or a HBT or BT of the inverted type.

7. FIGS. 7(a)-(b), relating to embodiment 6, show a different structure, in which, after forming the dummy emitter 20 as in FIG. 6(b), wet etching is carried out to expose the external base region 4c as shown in FIG. 7(a), and an undercut portion 15 is formed beneath the dummy emitter 20 by etching (FIG. 7(a)), and thereafter, using the process of (d) through (g) in FIG. 6, an emitter electrode metal layer 10f used to cover the emitter portion 8 in a form of umbrella as shown in FIG. 7(b) is formed, using dummy emitter 20.

8. By forming a multilayer structural material 16 by epitaxial growth of a high doping density n-type In_(x) Ga_(1-x) As layer 35 in which x carrier continuously from 0 to 1 (n-In_(x) Ga_(1-x) As (x=0 to 1) and a high doping density n-type InAs layer 36 on the multilayer structure material 7, an emitter electrode metal layer 10e is formed as shown in FIG. 8(b) by applying the method of embodiment 6. Since the work function of InAs is greater than that of the electrode metal, a low resistance emitter contact may be obtained without any alloying heat treatment. In the embodiment, In_(x) Ga_(1-x) As continuously varying in composition and InAs are formed in layers, but In_(x) Ga_(1-x) As of a specific composition may be also formed in a layer.

9. FIGS. 9(a)-(e) show a fabricating method of mushroom-shaped emitter electrode metal layer 10g. After forming an emitter portion 8 by etching as shown in FIG. 6(c), using the dummy emitter 20 as a mask, the surface is covered with a thin film of SiO_(x) of 3000Å in thickness, and a side wall 17 composed of SiO_(x) is formed on the sides of the emitter portion 8 and dummy emitter 20 by anisotropic dry etching using CHF₃ (FIG. 9(a)). Then the surface is coated and flattened with a photosensitive resist 21 (FIG. 9(b)), and the upper part of the dummy emitter 20 is exposed by dry etching using an oxygen plasma (FIG. 9(c)), and after removing Al 19 by HC1, an opening 22b with n⁺ -GaAs layer 6a exposed is formed by anisotropic dry etching using CHF₃ (FIG. 9(d)). In succession, AuGe, Ni, Ti and Au are evaporated in this order and lifted off, thereby forming an emitter electrode metal layer 10g.

10. By forming an Al_(x) Ga_(1-x) As layer 23 where x is 0.4 or more on the multilayer structural material in FIG. 6(a), the process of embodiment 9 is applied thereafter. However, in the process of FIG. 9(d), after removing the SiO_(x) layer 18 and also removing Al_(x) Ga_(1-x) As layer 23 by using acid, the emitter electrode metal layer 10g is formed. By this method, damage of n⁺ -GaAs layer 6a by dry etching may be prevented, and a clean n⁺ -GaAs layer 6a appears, so that an ohmic contact of high quality may be obtained. This method may be also applied in embodiments 6 to 8.

11. FIG. 11 shows a method of forming an external base region 4c of high dope p-type, by ion implantation of p-type dopant into the external base region 4c outside of the base region 4b below or corresponding on a plan view to the emitter electrode, using the dummy emitter 20 as a mask. After forming the structure of (c) in FIG. 6, Be⁺ is implanted using the dummy emitter 20 as mask (24), and it is heated to 750° C. for 10 seconds, so that a high doping density external base region 4c as shown in FIG. 11 is formed. Thereafter, applying the method of embodiment 6 shown in FIG. 6, the dummy emitter 20 is inverted to an emitter electrode metal layer 10e.

After ion implantation, it is necessary to anneal at a relatively high temperature, but adverse effects are not present because the n⁺ -GaAs layer 6 is covered with the SiO_(x) layer 18. Otherwise, Be⁺ may be implanted at the step of FIG. 6(b), or after etching until close to the external base region 4c, and then the external base may be exposed by etching. Or the implanted Be⁺ may penetrate even into the collection region 3. For this purpose, aside from Be⁺, Mg⁺ or Zn⁺ may be also used.

12. As shown in FIG. 12, after forming a dummy emitter 20 as in FIG. 6(b), Be⁺ is implanted, and part of GaAs layer 6 and Al_(x) Ga_(1-x) As layer 5 is etched off, and a thick external base region 4d is formed, so that the sheet resistance may be lowered. Thereafter, by applying the method shown in FIGS. 6(a)-(g), the dummy emitter 20 is inverted into an emitter electrode metal layer 10e.

13. FIG. 13 shows a method of forming a buried type collector 3a of the same size as the dummy emitter 20 by ion implantation, using the dummy emitter 20 as a mask. After the step shown in FIG. 6(c), a collector 3a substantially of the same size as the dummy emitter 20 and its peripheral insulating region 3b are formed by implanting O⁺ ions into the layer 3 using the dummy emitter 20 as a mask as shown in FIG. 13, and, by heat treatment at 750° C. for 10 seconds. Thereafter, by employing the method shown in FIGS. 6(a)-(g), the dummy emitter 20 is inverted into an emitter electrode metal layer 10e. Aside from O⁺, other ions such as B⁺ may be used. As in the embodiments 11 and 12, the heat treatment at high temperature is enabled owing to the existance of the SiO_(x) dummy emitter.

14. After forming an emitter electrode metal layer 10e (FIG. 6(g)), the collector region 3a substantially of same size as the emitter electrode metal layer 10e and its peripheral insulating region 3b are formed by implanting H⁺ ions which are implanted into a layer 3 for forming a collector, as shown in FIG. 14, using the emitter electrode metal layer 10e as a mask. In the case of H⁺ ion implantation, since heat treatment is not needed in the formation of the insulating region, the contact part formed between the emitter electrode metal layer 10e and emitter is protected from damage. Hence, it is possible to form a buried type collector region 3a by using H⁺.

15. After forming an umbrella-shaped emitter electrode metal layer 10f as shown in FIG. 7(b), base electrode metals 28 are evaporated and lifted off, using a photosensitive resist 27 and the electrode metal layer 10f as masks as shown in FIG. 15(a), and the base electrode metal layer 11c is formed outside of the base region 4b below or corresponding on a plan view to the electrode metal layer 10f. As a result, the base electrode 11c is formed by self-alignment at an extremely close distance from the emitter 5a, and the base resistance may be notably reduced.

16. After forming an umbrella-shaped emitter electrode metal layer 10f as shown in FIG. 7(b), the surface is coated with a thin film of SiO_(x) to a thickness of 3000Å, and by anisotropic dry etching using CHF₃, an SiO_(x) side wall 17 is formed on the sides around the emitter mesa 8 and electrode metal layer 10f as shown in FIG. 16(a). Furthermore, as shown in FIG. 16(b), base electrode metals 28 are evaporated and lifted off by using photosensitive resist 27 and the umbrella-shaped portion composed of electrode metal layer 10f and side wall 17 as masks. This forms the base electrode metal layer 11c in the external base region 4c outside of the base region 4b below or corresponding on a plan view to the electrode metal layer 10f and side wall 17, as shown in FIG. 16(b). Then the SiO_(x) side wall 17 is removed by buffer HF.

17. After forming an emitter electrode metal layer 10e (FIG. 6(g)), an SiO_(x) side wall 17 is formed on the sides around the emitter portion 8 and metal layer 10e, and a mask 27 of photosensitive resist is applied as shown in FIG. 17(a). In succession, the base electrode metal 28 is evaporated and lifted off, and a structure shown in FIG. 17(b) is formed. Then, the surface is covered with a photosensitive resist 21, and the upper portion of electrode metal layer 10e is exposed by dry etching using oxygen plasma as shown in FIG. 17(c). By etching away the metals 28 depositing on the side wall 17, the emitter electrode and base electrode are separated. As a result, as shown in FIG. 17(d), the base electrode metal layer 11c is formed at a distance of the width of side wall 17 with respect to emitter part 5a. Hence, the external base resistance may be reduced.

18. After forming a mushroom-shaped emitter electrode metal layer 10g as shown in FIG. 9(e), a mask 27 of photosensitive resist is formed as shown in FIG. 18(a), and base electrode metals 28 are evaporated and lifted off by using this mask 27 and the metal electrode layer 10g as mask. Consequently, a base electrode metal layer 11c is formed on the external base region 4c outside of the base region 4b below or corresponding on a plan view to the electrode metal layer 10g. As a result, the external base resistance can be reduced.

19. After the formation of the structure shown in FIG. 7(a), base electrode metals 28 are evaporated and lifted off by using a photosensitive resist 27 and dummy emitter 20 as masks as shown in FIG. 19(a). Consequently, a base electrode metal layer 11c is formed as shown in FIG. 11(b). Next, using the process of the inversion of the dummy emitter 20 into the emitter electrode metal layer as shown in embodiment 6, a structure corresponding to FIG. 15(b) is formed. As a result, the base electrode metal layer 11c is formed adjacent to the emitter 5a, and the base resistance may be lowered. In this method, incidentally, since the base electrode is formed first, it is important that the contact between the base electrode metal and external base is free from damage at the forming temperature of ohmic contact of emitter. In this embodiment, as the material used for base electrode metal, for example, Cr/Au or Cr/AuZn/Au may be used.

20. In the formation of structure in FIG. 9(a), a side wall 17 composed of SiN_(x) is formed in a method similar to that shown in FIG. 20(a), and base electrode metals 28 are evaporated and lifted off through the mast 27 of photosensitive resist as shown in FIG. 20(b). Thereafter, applying the method of separation of the base electrode from emitter electrode as shown in embodiment 17, and selectively removing SiN_(x) with respect to the dummy emitter 19, a structure as shown in FIG. 20(c) is formed. Then, conforming to the process of the inversion of the dummy emitter into the emitter electrode metal layer as shown in embodiment 6, the base electrode metal layer 11c is formed adjacent to the emitter part 5a. As in embodiment 19, it is necessary to select a metal, as a base electrode metal, whose ohmic contact forming temperature of the emitter. In this embodiment, contact forming temperature of the emitter. In this embodiment, the external base region 4c can also be exposed by etching until close to the region 4c before forming the side wall 17, and then by etching up to the region 4c.

21. FIGS. 21(a)-1 to (b)-3 show a method of forming an emitter including layer 9 as shown in FIG. 1 and an electrode metal layer 10a serving both as an emitter electrode and as an emitter electrode delineation metal. On the multilayer structure material 7 shown in FIGS. 6(a)-(g), a mask 29b corresponding to the size 29a of the base is formed as shown in FIG. 21(a), and oxygen ions are implanted into the layer 3 for forming the collector. Consequently, an insulating region 13 is formed. Then, on the portion 29a corresponding to the base region, an extension type dummy emitter 32 composed of an SiO_(x) layer 30 and an Al layer 31 extending from the emitter part to the insulation region 13 is formed by the method shown in embodiment 6 (FIG. 21(b)). Thereafter, according to the method shown in embodiment 7, an extension type emitter including layer 9 and an external base region 4c are formed (FIG. 21(c)), and an umbrella-shaped dummy emitter 32 is converted into an emitter electrode metal layer 10a. By employing this method, since the emitter electrode serves also as the emitter electrode delineation metal and it is formed by self-alignment corresponding to the emitter part, a bipolar transistor of a very small emitter size can also be fabricated. In this embodiment, although the method of forming an umbrella-shaped electrode metal layer is exhibited, the formation of the emitter electrode metal layer as disclosed in embodiments 6, 8, 9, 10 is also applicable.

22. FIGS. 22(a)-(b) show a method of forming, by self-alignment, a base electrode metal layer 11a serving as both the base electrode and the base electrode delineation metal and existing adjacent to the emitter portion, referring to a case of using an umbrella-shaped electrode metal layer. In the process shown in FIGS. 21(a)-1 to (b)-3, after forming an umbrella-shaped electrode metal layer 10a as shown in FIG. 1, a collector electrode 12a is formed as shown in FIG. 1, and H⁺ ions are implanted around the transistor. Consequently, an insulating region 14 ranging from the surface to substrate 1 is formed. Then, as shown in FIG. 22(a), base electrode metals 28 are evaporated and lifted off by using a photosensitive resist mask 27 and the umbrella-shaped emitter electrode metal layer 10a as a mask. Consequently, outside of the base region 4b below or corresponding on a plan view to the emitter electrode metal layer 10a, a base electrode metal layer 11a extending from the external base region to the peripheral insulating region 14 is formed. In this embodiment, although the method of embodiment 15 of using umbrella-shaped emitter electrode metal layer is employed, the method of formation of base electrode metal layer as disclosed in embodiments 16, 17, 18, 19, 20 is also applicable. 

What is claimed is:
 1. A bipolar transistor comprising:a first layer including a collector portion; a second layer formed on said first layer and including a base portion and an insulating portion; a third layer, including an emitter portion, formed on a part of said base portion and extending to cover a part of said insulating portion of said second layer; and an emitter electrode layer formed to cover an entire upper surface of said third layer wherein a part of said emitter electrode layer on a part of said third layer covering a part of said insulating portion of said second layer serves as an emitter electrode contact lead.
 2. A bipolar transistor as set forth in claim 1, wherein said third layer is made of a semiconductor material having a wider energy band gap than that of a material of said second layer.
 3. A bipolar transistor as set forth in claim 1, wherein a part of said third layer on said insulating portion of said second layer is of an insulating material.
 4. A bipolar transistor as set forth in claim 1, wherein said base portion of said second layer adjacent to a part thereof corresponding on a plan view to said emitter electrode layer has a lower sheet resistance than that of said base portion corresponding on a plan view to said emitter electrode layer.
 5. A bipolar transistor as set forth in claim 1, wherein said first layer adjacent a part thereof corresponding on a plan view to said emitter electrode layer is of an insulating material.
 6. A bipolar transistor as set forth in claim 1, wherein said emitter electrode layer is wider in width than said third layer, and wherein a base electrode layer is formed on said base portion of said second layer adjacent a part thereof corresponding on a plan view to said emitter electrode layer, said base electrode layer being extended to cover a part of said insulating portion of said second layer.
 7. A bipolar transistor comprising:a first layer including an emitter portion; a second layer formed on said first layer and including a base portion and an insulating portion; a third layer, including a collector portion, formed on a part of said base portion and extending to cover a part of said insulating portion of said second layer; and a collector electrode layer formed to cover an entire upper surface of said third layer wherein a part of said collector electrode layer on a part of said third layer covering a part of said insulating portion of said second layer serves as a collector electrode contact lead.
 8. A bipolar transistor as set forth in claim 7, wherein said first layer is made of a semiconductor material having a wider energy band gap than that of a material of said second layer.
 9. A bipolar transistor as set forth in claim 7, wherein a part of said third layer on said insulating portion of said second layer is of an insulating material.
 10. A bipolar transistor as set forth in claim 7, wherein said base portion of said second layer adjacent a part thereof corresponding on a plan view to said collector electrode layer has a lower sheet resistance than that of said base portion corresponding on a plan view to said collector electrode layer.
 11. A bipolar transistor as set forth in claim 7, wherein said first layer adjacent a part thereof corresponding on a plan view to said collector electrode layer is of an insulating material.
 12. A bipolar transistor as set forth in claim 7, wherein said collector electrode layer is wider in width than said third layer, and wherein a base electrode layer is formed on said base portion of said second layer adjacent a part thereof corresponding on a plan view to said collector electrode layer, said base electrode layer being extended to cover a part of said insulating portion of said second layer. 